We will use genetically engineered mice to study brain circuitry in an effort to understand the anatomical basis of Huntington's disease and a number of other more common degenerative brain diseases similar to Parkinson's disease. We will look at the brain in detail to decipher how the injured brain repais itself by making new connections and by producing new cells. We will also study supporting cells in the brain to determine if they play a beneficial role in this injury repair process.
Mechanisms Underlying Generation Of Febrile Seizures In Mouse Models Of Human Familial Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$304,559.00
Summary
Febrile Seizures (FS) affect 3% of children aged 0.5 - 6 yrs and have been proposed as an indicator of severe forms of adult generalized epilepsy. Mechanisms underlying FS generation are unknown although studies of Australian families suffering from epilepsy have linked 2 genes to FS. We have generated mice expressing these 2 genes. Aims and Outcomes: to investigate events triggering FS which will provide important insights into why FS occurs in children. (NB: CIA 2 yr career interruption)
I am a practicing neurologist with a clinical interest in movement disorders and dementia with an international reputation in neurosciences in the fields of neural stem cells, transgenic animal models of movement disorders and epilepsy. In line with my cl
Visualisation Of Functionally Activated Circuitry In The Brain
Funder
National Health and Medical Research Council
Funding Amount
$347,036.00
Summary
We are seeking to develop a method to precisely determine which parts of the brain are involved in the carrying out of different brain functions. The main advantage of our new method will be that we will be able to directly visualise the circuitry involved in a specified brain function. The brain is like a vast computer, with literally billions of connections between different parts, and it is these connections which are used to form functional circuits, which ultimately result in the brain cont ....We are seeking to develop a method to precisely determine which parts of the brain are involved in the carrying out of different brain functions. The main advantage of our new method will be that we will be able to directly visualise the circuitry involved in a specified brain function. The brain is like a vast computer, with literally billions of connections between different parts, and it is these connections which are used to form functional circuits, which ultimately result in the brain control of bodily function. Up until now, there has been no direct way of being able to directly visualise which of those billions of connections are involved in the formation of a circuit for any particular brain function. We plan to use a genetic approach to help to visualise functionally activated brain circuits. We know that some genes are turned on in the nerve cells which are activated during a brain function. We will use this knowledge to generate a new line of genetically engineered mice. In these mice, the genes which are turned on during brain activation will in turn be used to turn on special markers which will light up the activated circuits. This will be of great signficance in our understanding of brain function. It should also help us to understand what happens to these circuits in different diseases of the brain, such as following stroke, in senility, and Alzheimer's disease.Read moreRead less